A handle assembly is provided for a circuit breaker which includes a housing assembly that defines a substantially enclosed space housing an operating mechanism. The handle assembly is preferably a single-piece and includes a base member which is coupled to the operating mechanism, and a handle member having a first end which protrudes from an opening of the housing assembly, and a second end coupled to the base member. The base member includes first and second integral resilient legs which are disposed within the opening and are supported by posts protruding from the housing assembly, in order to resist undesired access into the substantially enclosed space therein. The first and second integral resilient legs each include a groove which increases the resiliency of the leg. The handle assembly is preferably symmetric about the longitudinal axis of the handle member.
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9. An electrical switching apparatus comprising:
a housing assembly defining a substantially enclosed space and a handle member opening;
an operating mechanism housed within said substantially enclosed space and including a handle arm; and
a handle assembly comprising:
a base member coupled to said handle arm of said operating mechanism, and
a handle member having a first end which protrudes from said handle member opening, and a second end coupled to said base member, wherein said base member includes first and second integral resilient legs which extend generally outwardly from said base member in order to resist undesired access through said handle member opening into said substantially enclosed space of said housing assembly,
wherein said housing assembly includes a first half shell and a second half shell, said first and second half shells being coupled together; wherein at least one of said first and second half shells of said housing assembly includes a first protrusion and a second protrusion; and wherein said first and second protrusions are structured to support said first and second integral resilient legs, respectively.
1. A handle assembly for an electrical switching apparatus including a housing assembly which defines a substantially enclosed space that houses an operating mechanism, and which includes an opening, said handle assembly comprising:
a base member structured to be coupled to said operating mechanism of said electrical switching apparatus; and
a handle member having a first end structured to protrude from said opening of said housing assembly, and a second end coupled to said base member, wherein said base member includes first and second integral resilient legs structured to be disposed within said opening of said housing assembly in order to resist undesired access into said substantially enclosed space therein,
wherein said base member and said handle member coupled thereto are movable among ON and OFF positions within said opening of said housing assembly,
wherein each of said first and second integral resilient legs includes an arcuate shape having a radius of curvature, and is structured to extend generally outwardly from said base member in order that said opening is substantially closed regardless of the position of said handle assembly with respect to said housing assembly, and
wherein when said base member and said handle member coupled thereto are disposed in one of said ON and OFF positions, one of said first and second integral resilient legs is deflected to an arcuate shape having a radius of curvature which is smaller than the radius of curvature of the arcuate shape of the other one of said first and second resilient legs.
8. An electrical switching apparatus comprising:
a housing assembly defining a substantially enclosed space and a handle member opening;
an operating mechanism housed within said substantially enclosed space and including a handle arm; and
a handle assembly comprising:
a base member coupled to said handle arm of said operating mechanism, and
a handle member having a first end which protrudes from said handle member opening, and a second end coupled to said base member, wherein said base member includes first and second integral resilient legs which extend generally outwardly from said base member in order to resist undesired access through said handle member opening into said substantially enclosed space of said housing assembly,
wherein said base member and said handle member coupled thereto are movable among ON and OFF positions within said opening of said housing assembly,
wherein each of said first and second integral resilient legs includes an arcuate shape having a radius of curvature, and extends generally outwardly from said base member in order that said opening is substantially closed regardless of the position of said handle assembly with respect to said housing assembly, and
wherein when said base member and said handle member coupled thereto are disposed in one of said ON and OFF positions, one of said first and second integral resilient legs is deflected to an arcuate shape having a radius of curvature which is smaller than the radius of curvature of the arcuate shape of the other one of said first and second integral resilient legs.
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U.S. patent application Ser. No. 11/254,529, filed Oct. 19, 2005, entitled “CIRCUIT BREAKER INCLUDING LINE CONDUCTOR HAVING BEND PORTION TO INCREASE CONTACT GAP”;
U.S. patent application Ser. No. 11/254,300, filed Oct. 19, 2005, entitled “CIRCUIT BREAKER INTERMEDIATE LATCH”;
U.S. patent application Ser. No. 11/254,298, filed Oct. 19, 2005, entitled “ELECTRICAL SWITCHING APPARATUS INCLUDING OPERATING MECHANISM HAVING INSULATING PORTION”;
U.S. patent application Ser. No. 11/254,514, filed Oct. 19, 2005, entitled “AUXILIARY SWITCH INCLUDING MOVABLE SLIDER MEMBER AND ELECTRIC POWER APPARATUS EMPLOYING SAME”;
U.S. patent application Ser. No. 11/254,299, filed Oct. 19, 2005, entitled “CONTACT ARM WITH 90 DEGREE OFFSET”;
U.S. patent application Ser. No. 11/254,535 filed Oct. 19, 2005, entitled “CIRCUIT BREAKER COMMON TRIP LEVER”;
U.S. patent application Ser. No. 11/254,509 filed Oct. 19, 2005, entitled “CIRCUIT BREAKER COMMON INTER-PHASE LINK”; and
U.S. patent application Ser. No. 11/254,515, filed Oct. 19, 2005, entitled “CIRCUIT BREAKER INTERMEDIATE LATCH STOP”.
1. Field of the Invention
The present invention relates to electrical switching apparatus and, more particularly, to circuit breakers including a handle assembly. The invention also relates to handle assemblies for electrical switching apparatus.
2. Background Information
Circuit breakers for telecommunication systems typically are smaller than circuit breakers associated with power distribution networks. A typical telecommunication system circuit breaker measures 2.5 inches high by 2.0 inches long by 0.75 inch thick, when the circuit breaker is viewed with the operating handle extending horizontally and moving in a vertical arc. While having a reduced size, the telecommunication system circuit breaker must still accommodate the various components and devices (e.g., separable contacts; trip device; operating mechanism) associated with larger circuit breakers. Thus, while the conventional components of a telecommunication system circuit breaker may not be unique, the necessity of having a reduced size requires specialized configurations and robust components that are different than power distribution circuit breakers. This is especially true where the telecommunication system circuit breakers are used in environments wherein the circuit breaker may be expected to operate for over 10,000 operating cycles and 50 tripping cycles; however, the reduced size telecommunication system circuit breakers are typically limited to a current rating of 30 amps.
The telecommunication system circuit breaker is structured to be disposed in a multi-level rack. The rack has multiple telecommunication system circuit breakers on each level. The rack, preferably, has a spacing between the levels of 1.75 inches; however, the current structure of telecommunication system circuit breakers, as noted above, have a height of 2.5 inches. As such, users have been required to adapt the multi-level rack to accommodate the taller telecommunication system circuit breakers. Circuit breakers disposed on the rack may be coupled to associated circuits. As such, if the current is interrupted in a first circuit, either due to the circuit breaker tripping or due to a user manually interrupting the circuit, it is sometimes desirable to interrupt the current on an associated second circuit. In the prior art, a common trip bar was structured to trip two adjacent circuit breakers. That is, a single trip bar extended across two circuit breakers and, if an over current condition occurred in either circuit, the actuation of the trip device caused the trip bar to rotate thereby tripping both circuit breakers. In smaller circuit breakers which have a low trip force, the use of a common trip bar is not feasible.
Thus, while existing telecommunication system circuit breakers are small, there is still a need for telecommunication system circuit breakers having a reduced height, especially a telecommunication system circuit breaker having a height of about, or less than, 1.75 inches; the preferred spacing between levels on the rack. As the size of the telecommunication system circuit breakers are reduced further, the need for robust, yet small, components which operate in a reduced space is increased. Accordingly, there is a need for a telecommunication system circuit breaker having a reduced size and an increased operating current range.
There is a further need to resist undesired access to internal components of the circuit breaker which could result, for example, in human injury or damage to electrical components. Specifically, it is desirable to avoid access through the opening in the circuit breaker housing from which the circuit breaker handle member protrudes. Conventionally, to restrict such access, a separate generally rigid slider member has been incorporated within the opening, being coupled to the base of the handle member. The slider typically includes a hole for receiving the handle end of the handle member and is structured to engage the base of the handle member in order to move therewith while providing a barrier to resist entry through the opening. See, e.g., U.S. Pat. No. 6,225,882. Such designs require two or more separately made parts (e.g., without limitation, the slider, and the handle member) and, to ensure proper and sufficient engagement between such separate parts, a complex interface geometry is required which adds to the cost of the handle assembly.
There is, therefore, room for improvement in handle assemblies for electrical switching apparatus and in circuit breakers employing handle assemblies.
These needs and others are met by the present invention, which is directed to an operating handle for an electrical switching apparatus.
As one aspect of the invention, a handle assembly is provided for an electrical switching apparatus including a housing assembly which defines a substantially enclosed space that houses an operating mechanism. The handle assembly comprises: a base member structured to be coupled to the operating mechanism of the electrical switching apparatus; and a handle member having a first end structured to protrude from an opening of the housing assembly, and a second end coupled to the base member, wherein the base member includes first and second integral resilient legs structured to be disposed within the opening of the housing assembly in order to resist undesired access into the substantially enclosed space therein.
The base member may be integral with the handle member in order that the handle assembly is a single-piece. The single-piece handle assembly may be made from a molded plastic material.
The base member and the handle member coupled thereto may be movable among ON and OFF positions within the opening of the housing assembly wherein each of the first and second integral resilient legs is arcuate shaped and structured to extend generally outwardly from the base member in order that the opening is substantially closed regardless of the position of the handle assembly with respect to the housing assembly. Each of the first and second integral resilient legs may include an end portion, a thickness and an undercut between the second end of the handle member and the end portion, in order to reduce the thickness at the location of the undercut thereby increasing the resiliency of the first and second integral resilient legs. The undercuts may be grooves.
The handle member may have a longitudinal axis wherein the handle assembly is symmetric with respect to the longitudinal axis. The base member may include a recess structured to receive a portion of the operating mechanism of the electrical switching apparatus.
As another aspect of the invention, an electrical switching apparatus comprises: a housing assembly defining a substantially enclosed space and a handle member opening; an operating mechanism housed within the substantially enclosed space and including a handle arm; and a handle assembly comprising: a base member coupled to the handle arm of the operating mechanism, and a handle member having a first end which protrudes from the handle member opening, and a second end coupled to the base member, wherein the base member includes first and second integral resilient legs which extend generally outwardly from the base member in order to resist undesired access through the handle member opening into the substantially enclosed space of the housing assembly.
The housing assembly may include a first half shell and a second half shell, the first and second half shells being coupled together wherein at least one of the first and second half shells of the housing assembly includes a first protrusion and a second protrusion. The first and second protrusions may be structured to support the first and second integral resilient legs, respectively. Each of the first and second integral resilient legs may be arcuate shaped and each of the first and second half shells of the housing assembly may include a handle side, wherein the first and second protrusions are structured to support the arcuate shaped legs between the first and second protrusions and the handle side of the at least one of the first and second half shells, respectively, in order that the handle member opening is substantially closed regardless of the position of the handle assembly with respect to the housing assembly. The first and second protrusions may be first and second posts protruding substantially laterally from the at least one of the first and second half shells.
The operating mechanism of the electrical switching apparatus may include a cradle wherein the first post is generally oblong shaped in order to accommodate movement of the cradle. The handle arm of the operating mechanism may include a bight member wherein the base member includes a recess structured to receive the bight member in order to secure the handle assembly to the handle arm.
A full understanding of the invention can be gained from the following description of the preferred embodiments when read in conjunction with the accompanying drawings in which:
As used herein, directional terms, such as “vertical,” “horizontal,” “left,” “right”, “clockwise,” etc. relate to the circuit breaker 10 as shown in most of the Figures, that is, with the handle assembly 400 located at the left side of the circuit breaker 10 (
The present invention is disclosed in association with a telecommunication system circuit breaker 10, although the invention is applicable to a wide range of circuit breakers for a wide range of applications such as but not limited to residential or molded case circuit breakers.
As shown in
The trip device 300 interacts with both the current path assembly 100 and the operating mechanism 200. The trip device 300 is structured to detect an over current condition in the current path assembly 100 and to actuate the operating mechanism 200 to move the contacts 110, 120 from the first, closed position to the second, open position. The handle assembly 400 includes a handle member 404 (described below), which protrudes from the housing assembly 20. The handle assembly 400 further interfaces with the operating mechanism 200 and allows a user to manually actuate the operating mechanism 200 and move the operating mechanism 200 between an on position, an off position, and a reset position.
As shown in
The housing assembly 20, preferably, has a length, represented by the letter “L” in
Within the enclosed space 46 (
As shown in
As seen in
The arc extinguisher assembly 150 includes arc extinguisher side plates 152, 153 within which are positioned spaced-apart generally parallel angularly offset arc chute plates 154 and an arc runner 156. As is known in the art, the function of the arc extinguisher assembly 150 is to receive and dissipate electrical arcs that are created upon separation of the contacts 110, 120 as the contacts 110, 120 are moved from the closed to the open position. The arc extinguisher assembly 150 also includes a gas channel 160 (
When installed in the housing assembly 20, the line conductor end portion 108 and the load conductor end portion 138 each extend through one of the conductor openings 68, 70 (
As shown best in
The operating mechanism 200 includes the cage 210 (
The handle arm 228 has an inverted, generally U-shaped body 282 with two elongated side plates 284A, 284B and a generally perpendicular bight member 286 extending between the handle arm side plates 284A, 284B. The bight member 286 includes at least one, and preferably two, spring mountings 288A, 288B. Each handle arm side plate 284A, 284B includes a generally circular distal end 290 structured to engage the cage 210 and act as a pivot. Each handle arm side plate 284A, 284B further includes an extension 292 having an opening 294. The handle arm side plate extension 292A, 292B extends generally perpendicular to the longitudinal axis of the associated handle arm side plate 284A, 284B while being in generally the same plane as the side plate 284A, 284B. A cradle reset pin 296 extends between the two handle arm side plate extension openings 294A, 294B.
The operating mechanism 200 is assembled as follows. The cage 210 (
The second link 224 is also pivotally coupled to the moving arm pivot pin 250 and extends, generally, toward the handle arm 228. More specifically, the moving arm pivot pin 250 extends through the second link pivot pin opening 264. The second link 224 is also pivotally coupled to the first link 222. More specifically, a link pivot pin 299 extends through the first link second pivot pin opening 263 and the second link first pivot pin opening 266. The first link first pivot pin opening 262, which may be a generally U-shaped slot, is coupled to a cradle body pivot pin 281. The primary spring 232, a tension spring, extends from the handle arm bight member spring mounting 288 to the link pivot pin 299.
In this configuration, the primary spring 232 generally biases the second link 224 and the cradle 220 generally toward the handle member 404, which in turn, biases the moving arm 122 and movable contact 120 to the second, open position. During normal operation with current passing through the circuit breaker 10, the trip device 300 holds the operating mechanism 200 in the closed position. As set forth above, when the operating mechanism 200 is in the closed position, the contacts 110, 120 are in electrical communication. More specifically, during normal operation, the cradle latch edge 278 is engaged by the trip device 300 thereby preventing the bias of the primary spring 232 from moving the operating mechanism 200 into the tripped position. When an over-current condition occurs, the trip device 300 disengages from the cradle latch edge 278 thereby allowing the bias of the primary spring 232 to move the operating mechanism 200 into a tripped position. With the operating mechanism 200 in the tripped position, the contacts 110, 120 are separated.
To return the circuit breaker 10 to the normal operating configuration, a user must move the operating mechanism 200 into the reset position wherein the cradle body latch edge 278 re-engages the trip device 300. That is, when the operating mechanism 200 is in the tripped position, the reset pin 296 is disposed adjacent to the arced bearing surface 280 on the cradle 220. When a user moves the handle assembly 400 (described below and coupled to the handle arm 228) to the reset position, the reset pin 296 engages the arced bearing surface 280 on the cradle 220 and moves the cradle 220 to the reset position as well. In the reset position, the cradle body latch edge 278 moves below, as shown in the figures, the intermediate latch operating mechanism latch 345 (described below) thereby re-engaging the trip device 300. Once the cradle body latch edge 278 re-engages the trip device 300, the user may move the operating mechanism 200 back to the closed position wherein the contacts 110, 120 are closed. Again, because the trip device 300 in engaged, the bias of the primary spring 232 is resisted and the operating mechanism 200 is maintained in the on position.
Additionally, the user may manually move the operating mechanism 200 to an open position which causes the contacts 110, 120 to be separated without disengaging the trip device 300. When a user moves the handle assembly 400 (described below and coupled to the handle arm 228) to the off position, the direction of the bias primary spring 232, that is the direction of the force created by the primary spring 232, changes so that the second link 224 moves independently of the cradle 220. Thus, the bias of the primary spring 232 causes the moving arm 122 to move away from the fixed contact 110 until the contacts 110, 120 are in the second, open position. As noted above, when the operating mechanism 200 is in the off position, the trip device 300 still engages the cradle 220. Thus, to close the contacts 110, 120 from the off position, a user simply moves the handle assembly 400 back to the on position without having to move to the reset position. As the user moves the handle assembly 400 to the on position, the direction of the bias primary spring 232 causes the second link 224 to move away from the handle member 404 thereby moving the moving arm 122 toward the fixed contact 110 and returning the contacts 110, 120 to the first, closed position.
As shown in
As shown in
As shown in
The distal end of each cylindrical member 354, 356 terminates in the keyed hub 360, 362. Each keyed hub 360, 362 includes a generally circular portion 372, 374 and a radial extension 376, 378. The keyed hub 360, 362 is structured to be disposed in a keyed opening 241A, 241B (
The trip device 300 is assembled as follows. The armature vertex tab 317 (
The trip bar 304 is rotatably coupled to the cage 210 with hubs 330, 332 disposed in opposed trip bar openings 243A, 243B. The actuator arm 322 extends away from the handle member 404 towards the armature second portion 314 and into the path of travel thereof. In this configuration, the trip bar 304 is structured to be rotated when engaged by the armature second portion 314. A trip bar spring 391 biases the trip bar 304 to a first, on position. When acted upon by the armature 308, the trip bar 304 rotates to a second, trip position (
The intermediate latch 306 is coupled to the cage 210 with a keyed hub 360, 362 rotatably disposed in a keyed opening 241A, 241B on each side plate 212A, 212B. As the intermediate latch 306 is rotated, the trip bar latch member 342 has an arcuate path of travel. The intermediate latch 306 is disposed just above the trip bar 304 so that the path of travel of the trip bar latch member 342 extends over the latch extension 324 and with the cradle passage 371 aligned with the cradle 220. In this configuration, when the operating mechanism 200 is in the on position, the cradle 220 is disposed within the cradle passage 371 with the cradle latch edge 278 engaging the operating mechanism latch 345. As noted above, the primary spring 232 biases the cradle 220 toward the handle member 404. Thus, the bias of the cradle 220 biases the intermediate latch 306 to rotate counter-clockwise as shown in
When an over-current condition occurs, the coil assembly 132 creates a magnetic field sufficient to overcome the bias of the armature return spring 310. As shown in
As shown in
As shown, for example, in
The base member 402 and handle member 404 coupled thereto are moveable within the handle member opening 52 among, for example, the ON position shown in
The base member 402 further includes a recess 424 structured to couple the handle assembly 400 to the handle arm 228 (
As will be understood with continued reference to
In the example of
While specific embodiments of the invention have been described in detail, it will be appreciated by those skilled in the art that various modifications and alternatives to those details could be developed in light of the overall teachings of the disclosure. Accordingly, the particular arrangements disclosed are meant to be illustrative only and not limiting as to the scope of the invention which is to be given the full breadth of the claims appended and any and all equivalents thereof.
Rodgers, Craig A., Brand, Ronald W.
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Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Oct 18 2005 | RODGERS, CRAIG A | Eaton Corporation | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 017132 | /0359 | |
Oct 19 2005 | Eaton Corporation | (assignment on the face of the patent) | / | |||
Oct 19 2005 | BRAND, RONALD W | Eaton Corporation | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 017132 | /0359 |
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